Rewiring marine food webs: Predicting consequences of species range shifts. This project aims to predict how changes in climate-driven species distributions affect shallow marine communities globally. Environmental change affects the structure, resilience and productivity of coastal marine ecosystems at regional and global scales. This project will combine global species distribution and trait databases, existing experimental data and targeted field sampling to develop, test and apply an integra ....Rewiring marine food webs: Predicting consequences of species range shifts. This project aims to predict how changes in climate-driven species distributions affect shallow marine communities globally. Environmental change affects the structure, resilience and productivity of coastal marine ecosystems at regional and global scales. This project will combine global species distribution and trait databases, existing experimental data and targeted field sampling to develop, test and apply an integrated modelling platform to predict how global warming-driven changes in species distributions and their interactions affect the structure and dynamics of shallow marine communities. This project addresses a knowledge gap on how species’ redistributions and trophic dynamics produce communities, and aims to forecast future species abundances for sustainable marine ecosystem management.Read moreRead less
Poleward bound: mechanisms and consequences of climate-driven species redistribution in marine ecosystems. Global redistribution of Earth's species is widely recognised as a fingerprint of climate change. However, the physiological and ecological processes that underpin such shifts in the distribution of marine species are poorly understood. Even less is known about why species respond at different rates, and how such widespread changes will impact the structure and function of Australia's marin ....Poleward bound: mechanisms and consequences of climate-driven species redistribution in marine ecosystems. Global redistribution of Earth's species is widely recognised as a fingerprint of climate change. However, the physiological and ecological processes that underpin such shifts in the distribution of marine species are poorly understood. Even less is known about why species respond at different rates, and how such widespread changes will impact the structure and function of Australia's marine ecosystems. This research will address critical knowledge gaps of why and how species respond in vastly different ways to environmental change. Research outcomes will improve the capacity to predict responses of marine species and ecosystems to climate change and provide advice relevant to strategic management of valuable natural resources.Read moreRead less